Foundations of Differential Geometry, 2 Volume Set
John Wiley & Sons Inc (Verlag)
978-0-470-55558-3 (ISBN)
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This two-volume introduction to differential geometry, part of Wiley's popular Classics Library, lays the foundation for understanding an area of study that has become vital to contemporary mathematics. It is completely self-contained and will serve as a reference as well as a teaching guide. Volume 1 presents a systematic introduction to the field from a brief survey of differentiable manifolds, Lie groups and fibre bundles to the extension of local transformations and Riemannian connections. Volume 2 continues with the study of variational problems on geodesics through differential geometric aspects of characteristic classes. Both volumes familiarize readers with basic computational techniques.
Shoshichi Kobayashi was born January 4, 1932 in Kofu, Japan. After obtaining his mathematics degree from the University of Tokyo and his Ph.D. from the University of Washington, Seattle, he held positions at the Institute for Advanced Study, Princeton, at MIT and at the University of British Columbia between 1956 and 1962, and then moved to the University of California, Berkeley, where he is now Professor in the Graduate School. Kobayashi's research spans the areas of differential geometry of real and complex variables, and his numerous resulting publications include several book: Foundations of Differential Geometry with K. Nomizu, Hyperbolic Complex Manifolds and Holomorphic Mappings and Differential Geometry of Complex Vector Bundles.
VOLUME I
Interdependence of the Chapters and the Sections xi
Chapter I
Differentiable Manifolds
1. Differentiable manifolds 1
2. Tensor algebras 17
3. Tensor fields 26
4. Lie groups 38
5. Fibre bundles 50
Chapter II
Theory of Connections
1. Connections in a principle fibre bundle 63
2. Existence and extension of connections 67
3. Parallelism 68
4. Holonomy groups 71
5. Curvature for and structure equation 75
6. Mappings of connections 79
7. Reduction theorem 83
8. Holonomy theorem 89
9. Flat connections 92
10. Local and infinitesimal holonomy groups 94
11. Invariant connections 103
Chapter III
Linear and Affine Connections
1. Connections in a vector bundle 113
2. Linear connections 118
3. Affine connections 125
4. Developments 130
5. Curvature and torsion tensors 132
6. Geodesics 138
7. Expressions in local coordinate systems 140
8. Normal coordinates 146
9. Linear infitesimal holonomy groups 151
Chapter IV
Riemannian Connections
1. Riemannian metrics 154
2. Riemannian connections 158
3. Normal coordinates and convex neighborhoods 162
4. Completeness 172
5. Holonomy groups 179
6. The decomposition theorem of de Rham 187
7. Affine holonomy groups
Chapter V
Curvature and Space Forms
1. Algebraic preliminaries 198
2. Sectional curvature
3. Spaces of constant curvature 204
4. Flat affine and Riemannian connections 209
Chapter VI
Transformations
1. Affine mappings and affine transformations 225
2. Infinitesimal affine transformations 229
3. Isometries and infinitesimal isometries 236
4. Holonomy and infinitesimal isometries 244
5. Ricci tensor and infinitesimal isometries 248
6. Extension of local isomorphisms 252
7. Equivalence problem 256
Appendices
1. Ordinary linear differential equations 267
2. A connected, locally compact metric space is separable 269
3. Partition of unity 272
4. On an arcwise connected subgroup of a Lie group 275
5. Irreducible subgroups of O(n) 277
6. Green's theorem 281
7. Factorization lemma 284
Notes
1. Connections and holonomy groups 287
2. Complete affine and Riemannian connections 291
3. Ricci tensor and scalar curvature 292
4. Spaces of constant positive curvature 294
5. Flat Riemannian manifolds 297
6. Parallel displacement of curvature 300
7. Symmetric spaces 300
8. Linear connections with recurrent curvature 304
9. The automorphism group of a geometric structure 306
10. Groups of isometries and affine transformations with maximum dimensions 308
11. Conformal transformations of a Riemannian manifold 309
Summary of Basic Notations 313
Bibliography 315
Index 325
Errata for Foundations of Differential Geometry, Volume I 330
Errata for Foundations of Differential Geometry, Volume II 331
VOLUME II
Chapter VII
Submanifolds
1. Frame bundles of a submanifold 1
2. The Gauss map 6
3. Covariant differentiation and second fundamental form 10
4. Equations of Gauss and Codazzi 22
5. Hypersurfaces in a Euclidean space 29
6. Type number and rigidity 42
7. Fundamental theorem for hypersurfaces 47
8. Auto-parallel submanifolds and totally geodesic submanifolds 53
Chapter VIII
Variations of the Length Integral
1. Jacobi fields 63
2. Jacobi fields in a Rimannian manifold 68
3. Conjugate points 71
4. Comparison theorem 76
5. The first and second variations of the length integral 79
6. Index theorem of Morse 88
7. Cut loci 96
8. Spaces of non-positive curvature 102
9. Center of gravity and fixed points of isometries 108
Chapter IX
Complex Manifolds
1. Algebraic preliminaries 114
2. Almost complex manifolds and complex manifolds 121
3. Connections in almost complex manifolds 141
4. Hermitian metrics and Kaehler metrics 146
5. Kaehler metrics in local coordinate systems 155
6. Examples of Kaehler manifolds 159
7. Holomorphic sectional curvature 165
8. De Rham decomposition of Kaehler manifolds 171
9. Curvature of Kaehler submanifolds 175
10. Hermitian connections in Hermitian vector bundles 178
Chapter X
Homogeneous Spaces
1. Invariant affine connections 186
2. Invariant connections on reductive homogeneous spaces 190
3. Invariant indefinite Riemannian metrics 200
4. Holonomy groups of invariant connections 204
5. The de Rham decomposition and irreducibility 210
6. Invariant almost complex structures 216
Chapter XI
Symmetric Spaces
1. Affine locally symmetric spaces 222
2. Symmetric spaces 225
3. The canonical connection on symmetric space 230
4. Totally geodesic submanifolds 234
5. Structure of symmetric Lie algebras 238
6. Riemannian symmetric spaces 243
7. Structure of orthogonal symmetric Lie algebras 246
8. Duality 253
9. Hermitian symmetric spaces 259
10. Examples 264
11. An outline of the classification theory
Chapter XII
Characteristic Classes
1. Weil homomorphism 293
2. Invaraint polynomials 298
3. Chern classes 305
4. Pontrjagin classes 312
5. Euler classes 314
Appendices
8. Integrable real analytic almost complex structures 321
9. Some definitions and facts on Lie algebras 325
Notes
12. Connections and holonomy groups (Supplement to Note 1) 331
13. The automorphism group of geometric structure (Supplement to Note 9) 332
14. The Laplacian 337
15. Surafces of constant curvature in R3 343
16. Index of nullity 347
17. Type number and rigidity of imbedding 349
18. Isometric imbeddings 354
19. Equivalence problems for Riemannian manifolds 357
20. Gauss-Bonnet theorem 358
21. Total curvature 361
22. Topology of Riemannian manifolds with positive curvature 364
23. Topology of Kaehler manifolds with positive curvature 368
24. Structure theorems on homogeneous complex manifols 373
25. Invariant connections on homogeneous spaces 375
26. Complex submanifolds 378
27. Minimal submanifolds 379
28. Contact structure and related structures 381
Bibliography 387
Summary of Basic Notations 455
Index for Volumes I and II 459
Errata for Foundations of Differential Geometry, Volume I 469
Errata for Foundations of Differential Geometry, Volume II 470
Erscheint lt. Verlag | 18.5.2009 |
---|---|
Reihe/Serie | Wiley Classics Library |
Verlagsort | New York |
Sprache | englisch |
Maße | 145 x 224 mm |
Gewicht | 1134 g |
Themenwelt | Mathematik / Informatik ► Mathematik ► Geometrie / Topologie |
ISBN-10 | 0-470-55558-0 / 0470555580 |
ISBN-13 | 978-0-470-55558-3 / 9780470555583 |
Zustand | Neuware |
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